Alfred O. Inman

Limitations and relative utility of screening assays to assess engineered nanoparticle toxicity in a human cell line

Single-walled carbon nanotubes (SWCNT), fullerenes (C(60)), carbon black (CB), nC(60), and quantum dots (QD) have been studied in vitro to determine their toxicity in a number of cell types. Here, we report that classical dye-based assays such as MTT and neutral red (NR) that determine cell viability produce invalid results with some NM (nanomaterials) due to NM/dye interactions and/or NM adsorption of the dye/dye products. In this study, human epidermal keratinocytes (HEK) were exposed in vitro to CB, SWCNT, C(60), nC(60), and QD to assess viability with calcein AM (CAM), Live/Dead (LD), NR, MTT, Celltiter 96 AQueous One (96 AQ), alamar Blue (aB), Celltiter-Blue (CTB), CytoTox Onetrade mark (CTO), and flow cytometry. In addition, trypan blue (TB) was quantitated by light microscopy. Assay linearity (R(2) value) was determined with HEK plated at concentrations from 0 to 25,000 cells per well in 96-well plates. HEK were treated with serial dilutions of each NM for 24 h and assessed with each of the viability assays. TB, CAM and LD assays, which depend on direct staining of living and/or dead cells, were difficult to interpret due to physical interference of the NM with cells. Results of the dye-based assays varied a great deal, depending on the interactions of the dye/dye product with the carbon nanomaterials (CNM). Results show the optimal high throughput assay for use with carbon and noncarbon NM was 96 AQ. This study shows that, unlike small molecules, CNM interact with assay markers to cause variable results with classical toxicology assays and may not be suitable for assessing nanoparticle cytotoxicity. Therefore, more than one assay may be required when determining nanoparticle toxicity for risk assessment.

Safety Evaluation of Sunscreen Formulations Containing Titanium Dioxide and Zinc Oxide Nanoparticles in UVB Sunburned Skin: An In Vitro and In Vivo Study

Sunscreens containing titanium dioxide (TiO(2)) and zinc oxide (ZnO) nanoparticles (NP) are effective barriers against ultraviolet B (UVB) damage to skin, although little is known about their disposition in UVB-damaged skin. Pigs were exposed to UVB that resulted in moderate sunburn. For in vitro studies, skin in flow-through diffusion cells were treated 24 h with four sunscreen formulations as follows: 10% coated TiO(2) in oil/water (o/w), 10% coated TiO(2) in water/oil (w/o), 5% coated ZnO in o/w, and 5% uncoated ZnO in o/w. TiO(2) (rutile, crystallite) primary particle size was 10 × 50 nm with mean agglomerates of 200 nm (range ca. 90 nm--460 nm); mean for ZnO was 140 nm (range ca. 60--200 nm). Skin was processed for light microscopy, scanning (SEM) and transmission electron microscopy (TEM), and time-of-flight secondary ion mass spectrometry (TOF-SIMS). UVB-exposed skin had typical sunburn histology. TEM showed TiO(2) NP 17 layers into stratum corneum (SC), whereas ZnO remained on the surface. TOF-SIMS showed TiO(2) and ZnO epidermal penetration in both treatments. Perfusate analyzed by TEM/energy dispersive x-ray spectroscopy or inductively coupled plasma mass spectrometry detected no Ti or Zn, indicating minimal transdermal absorption. In vivo, skin was dosed at 24 h occluded with formulations and at 48 h. TiO(2) NP in o/w formulation penetrated 13 layers into UVB-damaged SC, whereas only 7 layers in normal skin; TiO(2) in w/o penetrated deeper in UVB-damaged SC. Coated and uncoated Zn NP in o/w were localized to the upper one to two SC layers in all skin. By SEM, NP were localized as agglomerates in formulation on the skin surface and base of hair. TOF-SIMS showed Ti within epidermis and superficial dermis, whereas Zn was limited to SC and upper epidermis in both treatments. In summary, UVB-damaged skin slightly enhanced TiO(2) NP or ZnO NP penetration in sunscreen formulations but no transdermal absorption was detected.

Identification of the pathway of iontophoretic drug delivery : light and ultrastructural studies using mercuric chloride in pigs

Although electrically assisted transdermal drug delivery has recently achieved a great deal of research attention, the precise anatomical pathway followed by these drugs through the stratum corneum has not been clearly defined. Pigs are an accepted model for studying iontophoretic drug delivery in humans. The purpose of this investigation was to visualize the pathway of ion transport by iontophoresing mercuric chloride. Weanling Yorkshire swine were dosed with 7.4% mercuric chloride in the positive electrode at a current density of 200 µAmp/cm2 applied for 1 hr. Biopsies were immediately taken, exposed to 25% ammonium sulfide vapor to precipitate and localize the mercury, fixed, and processed for light and transmission electron microscopy. The presence of mercury, which appeared as a black precipitate, was confirmed using energy-dispersive X-ray microanalysis. Although some compound penetrated the skin through appendageal pathways, the electron micrographs clearly revealed that mercuric chloride traversed the intact stratum corneum via an intercellular route. Precipitate was also localized in the outer membrane of the mitochondria in the viable epidermal cells, dermal fibroblasts, and capillaries, demonstrating transdermal delivery and systemic exposure to the mercury. These findings have implications for iontophoretic drug delivery, since they allow visualization of the functional “pores” predicted by mathematical models.

Electron Microscopic Observations of Stratum Corneum Intercellular Lipids in Normal and Atopic Dogs

The barrier function of mammalian skin is maintained by intercellular stratum corneum lipids. In human patients with atopic dermatitis, an abnormal lipid barrier results in dry skin and increased transepidermal water loss. At this time, it is not known if a defective lipid barrier is present in atopic dogs. Normal and atopic canine skin were postfixed in ruthenium tetroxide and studied using transmission electron microscopy to determine structural differences within stratum corneum lipids. Intercellular lipid lamellae were graded on a semiquantitative scale. The deposition of stratum corneum lipid lamellae in atopic canine skin appeared markedly heterogeneous compared with that seen in normal canine skin. When present, the lamellae often exhibited an abnormal structure. The continuity and thickness of the intercellular lipid lamellae were significantly less in nonlesional atopic than in normal canine skin. These preliminary observations suggest that the epidermal lipid barrier is defective in atopic canine skin. Additional studies are needed to further characterize the biochemical defect and to possibly correct it with nutritional and/or pharmacologic intervention.

Topical Penetration of Piroxicam Is Dependent on the Distribution of the Local Cutaneous Vasculature

The mechanism of the topical delivery of piroxicam, a nonsteroidal antiinflammatory drug, has been controversial as to whether systemic absorption is required for topical efficacy. This study, using in vivo pigs treated with topical 3H-piroxicam gel, was designed to assess the role of systemic absorption on its delivery to deep tissues. Further, the role of the structure of the cutaneous vasculature (e.g., direct cutaneous or musculocutaneous) was studied. Finally, piroxicam delivery was measured using in vitro diffusion cells with pig skin obtained from the same sites to determine inherent permeability independent of vascular anatomy. These studies showed that penetration of the radiolabel occurred in subcutaneous and muscle tissue only under the dosed sites and not at the remote sites, ruling out systemic absorption as a prerequisite for local delivery. Tissue penetration in vivo was enhanced at the musculocutaneous compared to the direct cutaneous sites. In contrast, in vitro flux was identical in skin harvested from the two vascular sites, suggesting that the vasculature plays a pivotal role in deep tissue penetration of piroxicam. In conclusion, local delivery of topical drugs occurs independent of systemic absorption and the nature of the cutaneous vasculature at different sites must be taken into consideration for optimal delivery.

Determination of Lidocaine Concentrations in Skin After Transdermal Iontophoresis: Effects of Vasoactive Drugs

The purpose of this study was to investigate the effect of vasoactive drugs on transdermal lidocaine iontophoresis by measuring the concentrations of radiolabeled lidocaine which has penetrated the skin. Previous studies had demonstrated that coiontophoresis of vasoactive drugs could modulate the transcutaneous flux of lidocaine and suggested that a dermal depot of lidocaine was involved. To address this, lidocaine hydrochloride (14C) was iontophoresed in vivo in anesthetized weanling pigs either alone or with the vasodilator tolazoline or the vasoconstrictor norepinephrine. Tissue cores under the active electrode were then collected, quick-frozen, and sectioned on a cryostat, and then the radioactivity was determined in each 40-µm section. Coiontophoresis with norepinephrine resulted in increased concentrations of lidocaine in skin up to a depth of 3 mm. These concentrations decreased to lidocaine-alone levels after a 4-hr washout. Tolazoline decreased tissue concentrations of lidocaine. Concentrations were intermediate when lidocaine alone was administered. These studies support the hypothesis that coiontophoresis of vasoactive drugs modulates the transdermal delivery of lidocaine, in part by altering the cutaneous “depot.”

Quantum dot penetration into viable human skin.

Abstract Systematic studies probing the effects of nanoparticle surface modification and formulation pH are important in nanotoxicology and nanomedicine. In this study, we use laser-scanning fluorescence confocal microscopy to evaluate nanoparticle penetration in viable excised human skin that was intact or tape-stripped. Quantum dot (QD) fluorescent nanoparticles with three surface modifications: Polyethylene glycol (PEG), PEG-amine (PEG-NH2) and PEG-carboxyl (PEG-COOH) were evaluated for human skin penetration from aqueous solutions at pH 7.0 and at pHs of solutions provided by the QD manufacturer: 8.3 (PEG, PEG-NH2) and 9.0 (PEG-COOH). There was some penetration into intact viable epidermis of skin for the PEG-QD at pH 8.3, but not at pH 7.0 nor for any other QD at the pHs used. Upon tape stripping 30 strips of stratum corneum, all QDs penetrated through the viable epidermis and into the upper dermis within 24 h.

Comparison of an In Vitro Skin Model to Normal Human Skin for Dermatological Research

EpiDerm™, an in vitro human skin equivalent (HSE), was compared to normal human breast skin (NHS) to morphologically and biochemically assess its feasibility for dermatological research. Intralot and interlot variability was studied in day 0, 1, 2, and 3 in vitro cultures and in day 0, 3, 5, and 7 NHS. For NHS, light microscopy (LM) at day 0 showed stratified epidermis which exhibited an increase in vacuoles and dark basal cells as storage increased to 3, 5, and 7 days. Transmission electron microscopy (TEM) revealed typical organelles in the epidermis and a convoluted basement membrane at day 0. With increased storage, vacuoles and paranuclear clefts became numerous, necrosis increased, tonofilaments became less organized, and overall cellular integrity decreased. Biochemical data showed consistent MTT and glucose utilization (GU) through day 5, while lactate production decreased to 75% by day 3. By LM, day 0 HSE consisted of a thick, compact, stratum corneum that sent projections between the stratum granulosum cells. By TEM, the configuration, organization, differentiation, distribution, and frequency of the organelles differed slightly from NHS. In addition, the basement membrane of the HSE was not completely differentiated, and the dermis was thin and acellular. Although day 1 and 2 cultures showed little change, day 3 exhibited an overall degeneration. Biochemical analysis showed GU and lactate production decreased through day 3. In conclusion, the EpiDerm™ HSE, although exhibiting slight differences, was morphologically and biochemically similar to normal human epidermis and may be a valuable model in assessing the toxicology, metabolism, or pharmacology of nonvesicating compounds. Microsc. Res. Tech., 37:172–179, 1997.

Effect of Selective Lipid Extraction from Different Body Regions on Epidermal Barrier Function

AbstractPurpose. To assess the effects of selective lipid extraction and tape stripping on transepidermal water loss (TEWL) at three body regions in the pig. Methods. Lipids were extracted from the abdominal, inguinal, and back regions using three different solvent extraction procedures or cellophane tape stripping (15×) on Yorkshire pigs. Three solvent extraction stages were I, cyclohexane (5 ml for three, 1-min extractions); II, cyclohexane/ethanol (4:1) (5 ml for three, 1-min extractions); and III, cyclohexane/ethanol (1:4) (5 ml for three, 3-min extractions) extracted as follows: Site A, Stage I; Site B, Stage I and II; Site C, Stage I, II and III. Erythema, edema, and TEWL were assessed in control, tape-stripped, and extracted sites at 0, 6, and 24 h. The extracted lipids were analyzed by thin layer chromatography and quantified by densitometry for ceramide, cholesterol, cholesterol esters, fatty acids, and triglycerides. Results. The change in TEWL (Δ TEWL) in 14 of the 15 sites was the highest at 24 h and generally increased with each additional extraction. The greatest changes were present in the back. Each extraction stage removed specific lipids in reproducible quantities that caused the Δ TEWL to increase from 0 to 24 h. Lipid removal was verified by transmission electron microscopy. The mean total lipid concentration depended on extraction solvents and body region, and was reproducible across sites and regions at equivalent stages of lipid extraction. Relative proportions of individual lipids extracted were similar across all body regions. Higher concentrations of total lipids were extracted from the back. Conclusions. These studies demonstrate that extraction of lipids increased the Δ TEWL to a level similar to repeated tape stripping at all body sites in the pig. This study suggested that strategies that could biochemically alter epidermal lipid composition may increase absorption of simultaneously administered topical compounds and may be useful to enhance drug delivery.

Interactions of aluminum nanoparticles with human epidermal keratinocytes

Aluminum nanoparticles (Al NP) have been used in applications as diverse as drug delivery, material surface coatings and an ingredient for solid rocket fuel in military explosives and artillery. Although Al NP are used in many civilian and military applications, the health and safety implications of these nanosize particles are not known. To understand the interactions and biological activity of Al NP in human cells, cultured human neonatal epidermal keratinocytes (HEK) were exposed for 24 h to 50 and 80 nm Al NP in concentrations from 4.0 to 0.0004 mg ml−1 to assess the cytotoxicity and inflammatory potential. UV–Vis measurements and nanoparticle controls revealed that the Al NP interact with the assay dyes. Viability did not decrease in HEK exposed to both the 50 and the 80 nm Al NP at all treatment concentrations with MTT, CellTiter 96® AQueous One (96 AQ) and alamar Blue® (aB) viability assays. The 96 AQ and aB assays interact with the Al NP less than MTT, and proved to be the best assays to use with these Al NP. TEM depicted Al NP localized within the cytoplasmic vacuoles of the cells. Cytokine data was variable, indicating possible nanoparticle interactions with the cytokine assays. These studies illustrate the difficulties involved in assessing the biological safety of nanomaterials such as Al NP due to media‐ and temperature‐dependent particle agglomeration and nanoparticle interactions with biomarkers of cytotoxicity. Copyright